Fatty Acid Pathways Wyandanch NY

Fatty acids exist in the body primarily as triglycerides and phospholipids. Phospholipids make up the bilipid membrane of cells and the membranes of organelles within the cytoplasm. Fatty acids are split from the triglyceride glycerol backbone and broken down into carbon fragments which are then oxidized to provide energy.

Fatty acids exist in the body primarily as triglycerides and phospholipids. Phospholipids make up the bilipid membrane of cells and the membranes of organelles within the cytoplasm. Fatty acids are split from the triglyceride glycerol backbone and broken down into carbon fragments which are then oxidized to provide energy. Usually, just the 16 carbon fatty acids or shorter are metabolized in this fashion.

[ Fatty Acid Break Down Image ]

Fatty acids 16 carbons and longer from the omega-3 and -6 families can undergo the formation of double bonds and chain lengthening to create compounds called eicosanoids. These substances are autacoids, evanescent compounds which exert their effects locally in the microenvironment of the tissues where they are generated.1 Eicosanoids are cyclic oxygenated derivatives of fatty acids consisting of prostaglandins, leukotrienes, thromboxanes, prostacyclines, and lipoxins which are the moderators of life processes at the microcellular and tissue level (Fig. 14). They are intermediate between biochemicals and hormones. Their presence in extremely small nano and pico molar amounts exerts effects which are more powerful by many fold than various potent organ level hormones.

[ Functions Of Eicosanoids Image ]

Eicosanoids are regulatory, turning various life processes on and off. For example, eicosanoids can stimulate the clotting mechanism when blood vessels are injured, but they can also stop the clotting mechanism so it does not proceed to the point where circulation other than at the local site of injury is impaired.

Eicosanoids must exist in precise balances for life to continue without the presence of disease. Since the various eicosanoids are produced from dietary fatty acids, modifying the diet can shift eicosanoid balances. Overconsumption of one kind of fatty acid may overproduce one kind of eicosanoid. Its effect will then become predominant and not be properly balanced by its antagonistic eicosanoid and thus disease may result. For example, the overconsumption of omega-6 fatty acids can create eicosanoids which promote inflammation. If these fatty acids are consumed in excess at the expense of a balancing amount of omega-3 fatty acids, inflammatory diseases such as arthritis, cardiovascular disease, and allergic conditions may result. Balance is the essence of life.

The various metabolic pathways leading to the production of eicosanoids are complex. The pathways begin with the types of fatty acids in the diet. These in turn are converted by enzyme systems into progressively longer and more unsaturated fatty acids until they reach their eicosanoid destination. Figures 15 and 16 outline these synthetic pathways.

Desaturase and elongase enzymes responsible for these conversions vary in functionality from species to species, within the same species, and even within the same individual under differing circumstances. Additionally, it is believed, these enzyme systems can be affected adversely by various toxins and disease states. Thus not only diet, but environmental and genetic factors can influence eicosanoid balances.

In animal species, sufficient enzyme systems do not exist to permit formation of unsaturated bonds in the omega-3 and the omega-6 positions. Therefore, as discussed previously,

[ Fatty Acid Modification Image ]

[ Eicosanoid Pathways Image ]

omega-3 and -6 fatty acids are essential dietary constituents. Plant chloroplasts, on the other hand, have the enzyme systems necessary to form these omega-3 and -6 fatty acids and thus plant food sources become the ultimate source of these essential fatty acids for animals. This means even if an animal is a carnivore, it is consuming prey which in turn has consumed plant material containing these essential fatty acids. Such is the case for fish which concentrate high levels of omega-3 coming up to them through the food chain from phytoplankton.

A natural diet consisting of fresh, raw foods provides an entirely different spectrum of fatty acids than does the modern fare of fractionated, processed, stored, and otherwise altered foods. In a natural diet a wide range of fatty acids will be supplied in their biologically protected and active form. Fatty acids of the omega-3, -6 and -9 families will all be present in the ratios in which life was originally adapted to utilize them. Under these circumstances, eicosanoids are more likely to be properly in balance.

In the modem diet, however, it is possible to receive virtually no omega-3 fatty acids, extremely high levels of saturated fatty acids, oxidized cholesterol, trans-fatty acids and other isomers, and large proportions of omega-6 fatty acids as well as various oxidized forms of these fatty acids which result inevitably from processing. Such conditions imbalance eicosanoids by providing improper starting materials for eicosanoid synthesis and by introducing toxic elements which interfere with enzymatic pathways.

Proper nutrition should therefore be directed toward restoring the natural, unaltered diet and the elimination, as much as possible, of foods comprised of lipids in inappropriate ratios and altered from their natural forms.

About the Author:

Dr. Randy Wysong: A former veterinary clinician and surgeon, college instructor in human anatomy, physiology and the origin of life, inventor of numerous medical, surgical, nutritional, athletic and fitness products and devices, research director for the present company by his name and founder of the philanthropic Wysong Institute. http://www.wysong.net. Also check out http://www.cerealwysong.com.

In almost every nutrition and herbal store, evening primrose oil is marketed as a treatment for a wide range of medical illnesses. The major ingredient in primrose oil is omega 6 fatty acid (gamma linolenic acid). The major use of primrose is in the use of disorders where the defect is metabolic or biochemical.